Linking up pressure, chemical potential and thermal gradients

Montel, François; Hoang, Hai; Galliéro, Guillaume

doi:10.1140/epje/i2019-11821-0

Cited by 9 publications

(11 citation statements)

References 14 publications

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“…The modeling frameworks for the estimation of compositional variation with depth in petroleum reservoirs have been reported in the literature. ,− There are three main categories of these modeling frameworks . The thermodynamic based models (static models) rely on fluid enthalpies to estimate the thermal diffusion coefficient. ,,− The second category is based on activation energy (dynamic models), which is obtained from viscosity correlations. ,− The third category requires a molecular diffusion coefficient and convection term. ,− …”

Section: Modeling Methodologymentioning

confidence: 99%

“…29,[31][32][33] The third category requires molecular diffusion coefficient and convection term. 29,[33][34][35][36][37][38][39][40][41] CG models in the above mentioned second and third categories were not considered in this study because they are not supported by the applied CMG's WinProp simulator. To include these models in this study would require developing separate solution algorithms for each of them,…”

Section: Compositional Grading Modelsmentioning

confidence: 99%

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Technical Implications of Neglecting Compositional Grading Effects in Petroleum Reservoir Simulation Models

et al. 2020

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Most compositional reservoir simulation practices assumes that the compositions of various fluid components are the same at all locations within the reservoir system. This constant composition assumption is incorrect and unrealistic as it grossly ignores the occurrences of some less obvious physical processes in the reservoir. Gravitational force, temperature gradient and thermal diffusion, amongst other factors, contributes to distribution and gradation of hydrocarbon fluid compositions in the reservoir. Therefore, incorporating compositional grading models that Page 2 of 47 adequately accounted for the individual and combined effects of gravity force, temperature gradient, and thermal diffusion is crucial when initializing reservoir simulation models. This research seeks to elucidate the technical implications of compositional grading on improved reserve estimation and reservoir performance prediction. The mathematical framework for the compositional grading modeling is based on one-dimensional zero-mass-flow stationary state assumption. The Computer Modelling Group's equation of state multiphase equilibrium property simulator, WinProp, was used for the fluid modeling while Computer Modelling Group's compositional reservoir simulator, GEM, was used for the reservoir modeling and simulation. In the absence of historical production data, Computer Modelling Group's CMOST was used to perform uncertainty assessment for the validation of the initialized reservoir models. The research results show that initialized reservoir models that neglected or inadequately accounted for compositional grading effects, overestimated oil in-place and underestimated gas in-place. Constant composition (without compositional grading) initialized reservoir model overestimate ultimate cumulative oil production by 14.271 MMbbl more than the isothermal compositional grading model, and 24.088 MMbbl more than the Kempers thermal diffusion compositional grading initialized reservoir model. It underestimated ultimate cumulative gas production by 30.133 Bft 3 less than the isothermal compositional grading, and 50.408 Bft 3 less than the Kempers thermal diffusion compositional grading initialized reservoir model. These figures suggest that neglecting compositional grading or inadequate account of compositional grading effects in reservoir simulation initialization, has detrimental technical consequences.

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Section: Modeling Methodologymentioning

confidence: 99%

Section: Compositional Grading Modelsmentioning

confidence: 99%

Technical Implications of Neglecting Compositional Grading Effects in Petroleum Reservoir Simulation Models

et al. 2020

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“…Pedersen and Lindeloff (2003) assumed a stationary state with an influence of temperature gradient and expressed the change in component compositions in terms of thermodiffusion coefficients depending on partial molar enthalpies of the components. As the gravitational segregation is well quantified, the current practice in the petroleum industry consists of tuning the thermodiffusion parameters to match the available compositional field data (Montel et al, 2019).…”

Section: Introductionmentioning

confidence: 99%

A new approach to thermal segregation in petroleum reservoirs: Algorithm and case studies

Baghooee

Montel

Galliéro

et al. 2021

Journal of Petroleum Science and Engineering

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“…For diluted gas mixtures, the answers, again, are given by the gas kinetic theory [45]. Recently, a simplified approach to thermodiffusion was suggested specifically for the transport in porous media [46]. The simplification is needed since the experimental determination of the thermodiffusion coefficients in multicomponent mixtures is a difficult task [47,48].…”

Section: Introductionmentioning

confidence: 99%

Thermodynamic Theory of Diffusion and Thermodiffusion Coefficients in Multicomponent Mixtures

Shapiro

2020

Journal of Non-Equilibrium Thermodynamics

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Transport coefficients (like diffusion and thermodiffusion) are the key parameters to be studied in non-equilibrium thermodynamics. For practical applications, it is important to predict them based on the thermodynamic parameters of a mixture under study: pressure, temperature, composition, and thermodynamic functions, like enthalpies or chemical potentials. The current study develops a thermodynamic framework for such prediction. The theory is based on a system of physically interpretable postulates; in this respect, it is better grounded theoretically than the previously suggested models for diffusion and thermodiffusion coefficients. In fact, it translates onto the thermodynamic language of the previously developed model for the transport properties based on the statistical fluctuation theory. Many statements of the previously developed model are simplified and amplified, and the derivation is made transparent and ready for further applications. The n(n+1)/2 independent Onsager coefficients are reduced to 2n+1 determining parameters: the emission functions and the penetration lengths. The transport coefficients are expressed in terms of these parameters. These expressions are much simplified based on the Onsager symmetry property for the phenomenological coefficients. The model is verified by comparison with the known expressions for the diffusion coefficients that were previously considered in the literature.

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Linking up pressure, chemical potential and thermal gradients

Cited by 9 publications

References 14 publications

Technical Implications of Neglecting Compositional Grading Effects in Petroleum Reservoir Simulation Models

Technical Implications of Neglecting Compositional Grading Effects in Petroleum Reservoir Simulation Models

A new approach to thermal segregation in petroleum reservoirs: Algorithm and case studies

Thermodynamic Theory of Diffusion and Thermodiffusion Coefficients in Multicomponent Mixtures

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